Е. Н. Добров scite author profile

Potato virus A (PVA) particles were bombarded with thermally activated tritium atoms, and the intramolecular distribution of the label in the amino acids of the coat protein was determined to assess their in situ steric accessibility. This method revealed that the N-terminal 15 amino acids of the PVA coat protein and a region comprising amino acids 27 to 50 are the most accessible at the particle surface to labeling with tritium atoms. A model of the spatial arrangement of the PVA coat protein polypeptide chain within the virus particle was derived from the experimental data obtained by tritium bombardment combined with predictions of secondary-structure elements and the principles of packing ␣-helices and ␤-structures in proteins. The model predicts three regions of tertiary structure: (i) the surface-exposed N-terminal region, comprising an unstructured N terminus of 8 amino acids and two ␤-strands, (ii) a C-terminal region including two ␣-helices, as well as three ␤-strands that form a two-layer structure called an abCd unit, and (iii) a central region comprising a bundle of four ␣-helices in a fold similar to that found in tobacco mosaic virus coat protein. This is the first model of the three-dimensional structure of a potyvirus coat protein.

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The organization of potato virus X coat proteins in virus particles studied by tritium planigraphy and model building

Baratova

Grebenshchikov

Добров

et al. 1992

Virology

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One more probable structural transition in potato virus X virions and a revised model of the virus coat protein structure

et al. 2008

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We found that a 2-h incubation of potato virus X (PVX) virions in 10 mM Tris-HCl buffer pH 7.5 at -20 degrees C results in a strong but reversible drop in virion stability. Under these conditions, the PVX virions are completely disrupted by low (starting from 50 mM) concentrations of LiCl and CaCl(2) but not of NaCl. Incubation of PVX samples with 0.05-2 M LiCl at +4 degrees C did not result in virion disassembly and the virions were not disrupted upon incubation at -20 degrees C in 10 mM Tris-HCl buffer pH 7.5 without LiCl. We suggest that a 2-h incubation of the PVX virions at -20 degrees C in 10 mM Tris-HCl pH 7.5 results in a structural transition in the virus particles. A revised model of the three-dimensional organization of coat protein subunits in the PVX virions is proposed. This two-domain model explains better the high plasticity of the PVX CP structure.

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β-structure of the coat protein subunits in spherical particles generated by tobacco mosaic virus thermal denaturation

Добров¹,

Nikitin²,

Trifonova³

et al. 2013

Journal of Biomolecular Structure and Dynamics

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Conversion of the rod-like tobacco mosaic virus (TMV) virions into "ball-like particles" by thermal denaturation at 90-98 °C had been described by R.G. Hart in 1956. We have reported recently that spherical particles (SPs) generated by thermal denaturation of TMV at 94-98 °C were highly stable, RNA-free, and water-insoluble. The SPs were uniform in shape but varied widely in size (53-800 nm), which depended on the virus concentration. Here, we describe some structural characteristics of SPs using circular dichroism, fluorescence spectroscopy, and Raman spectroscopy. It was found that the structure of SPs protein differs strongly from that of the native TMV and is characterized by coat protein subunits transition from mainly (about 50%) α-helical structure to a structure with low content of α-helices and a significant fraction of β-sheets. The SPs demonstrate strong reaction with thioflavin T suggesting the formation of amyloid-like structures.

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Tritium planigraphy study of structural alterations in the coat protein of Potato virus X induced by binding of its triple gene block 1 protein to virions

et al. 2009

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Alterations in Potato virus X (PVX) coat protein structure after binding of the protein, encoded by the first gene of PVX triple gene block (triple gene block 1 protein, TGBp1), to the virions were studied using tritium planigraphy. Previously, it has been shown that TGBp1 molecules interact with the PVX particle end, containing the 5′‐terminus of PVX RNA, and that this interaction results in a strong decrease in virion stability and its transformation to a translationally active state. In this work, it has been shown that the interaction of TGBp1 with PVX virions leads to an increase of ∼ 50% in tritium label incorporation into the 176–198 segment of the 236‐residue‐long PVX coat protein subunit, with some decrease in label incorporation into the N‐terminal coat protein region. According to the new ‘sandwich’ variant of our recently proposed model of the three‐dimensional structure of the intravirus PVX coat protein, the 176–198 segment is assigned to the β‐sheet region located at the subunit surface, presumably participating in coat protein interactions with the intravirus RNA and/or in protein–protein interactions, whereas the N‐terminal coat protein region corresponds to the other part of the same β‐sheet. For the remaining segments of the PVX coat protein subunit, no significant difference between tritium incorporation into untreated and TGBp1‐treated PVX was observed. A detailed description of the ‘sandwich’ version of the intravirus PVX coat protein model is presented.

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